Inequalities for norms of derivatives of non-periodic functions with non-symmetric constraints on higher derivatives

The Coarse Scale Velocity

10.23943/princeton/9780691174822.003.0015 ◽

2017 ◽

Author(s):

Philip Isett

Keyword(s):

Velocity Field ◽

Building Blocks ◽

Coarse Scale ◽

Divergence Equation ◽

Higher Derivatives ◽

Order Of Magnitude ◽

Derivatives Of

This chapter deals with the coarse scale velocity. It begins the proof of Lemma (10.1) by choosing a double mollification for the velocity field. Here ∈ᵥ is taken to be as large as possible so that higher derivatives of velement are less costly, and each vsubscript Element has frequency smaller than λ‎ so elementv⁻¹ must be smaller than λ‎ in order of magnitude. Each derivative of vsubscript Element up to order L costs a factor of Ξ‎. The chapter proceeds by describing the basic building blocks of the construction, the choice of elementv and the parametrix expansion for the divergence equation.

The properties of Bessel-type fractional derivatives and integrals

JOURNAL OF ADVANCES IN PHYSICS ◽

10.24297/jap.v11i8.203 ◽

2016 ◽

pp. 3973-3982

Author(s):

V. R. Lakshmi Gorty

Keyword(s):

Fractional Order ◽

Real Line ◽

Computer Algebra System ◽

Fractional Derivatives ◽

Graphical Representation ◽

Fractional Integrals ◽

The Real ◽

Fractional Derivatives And Integrals ◽

Half Axis ◽

Derivatives Of

The fractional integrals of Bessel-type Fractional Integrals from left-sided and right-sided integrals of fractional order is established on finite and infinite interval of the real-line, half axis and real axis. The Bessel-type fractional derivatives are also established. The properties of Fractional derivatives and integrals are studied. The fractional derivatives of Bessel-type of fractional order on finite of the real-line are studied by graphical representation. Results are direct output of the computer algebra system coded from MATLAB R2011b.

The Perception of the Higher Derivatives of Visual Motion.

10.21236/ada171076 ◽

1986 ◽

Cited By ~ 1

Author(s):

Lloyd Kaufman ◽

Samuel J. Williamson

Keyword(s):

Visual Motion ◽

Higher Derivatives ◽

Derivatives Of

On finite sums of periodic functions

Georgian Mathematical Journal ◽

10.1515/gmj-2019-2076 ◽

2020 ◽

Vol 27 (2) ◽

pp. 265-269

Author(s):

Alexander Kharazishvili

Keyword(s):

Analytic Function ◽

Real Line ◽

Real Analytic Function ◽

Periodic Functions ◽

Uniform Limit ◽

The Real ◽

Pointwise Limit ◽

Finite Sums ◽

Real Analytic

AbstractIt is shown that any function acting from the real line {\mathbb{R}} into itself can be expressed as a pointwise limit of finite sums of periodic functions. At the same time, the real analytic function {x\rightarrow\exp(x^{2})} cannot be represented as a uniform limit of finite sums of periodic functions and, simultaneously, this function is a locally uniform limit of finite sums of periodic functions. The latter fact needs the techniques of Hamel bases.

On the Zeros of Higher Derivatives of Hardy'sZ-Function

Journal of Number Theory ◽

10.1006/jnth.1998.2341 ◽

1999 ◽

Vol 75 (2) ◽

pp. 262-278 ◽

Cited By ~ 1

Author(s):

Kohji Matsumoto ◽

Yoshio Tanigawa

Keyword(s):

Higher Derivatives ◽

Derivatives Of

Extensions of Otto Toeplitz’ Combinatorial Construction of Almost Periodic Functions on the Real Line

Toeplitz Centennial - Operator Theory: Advances and Applications ◽

10.1007/978-3-0348-5183-1_17 ◽

1982 ◽

pp. 303-311

Author(s):

Hans Haller ◽

Konrad Jacobs

Keyword(s):

Real Line ◽

Almost Periodic Functions ◽

Almost Periodic ◽

Periodic Functions ◽

The Real ◽

Combinatorial Construction

Some remarks on incomplete gamma type function γ*(α, x_)

Filomat ◽

10.2298/fil1501125o ◽

2015 ◽

Vol 29 (1) ◽

pp. 125-131 ◽

Cited By ~ 1

Author(s):

Emin Özcağ ◽

İnci Egeb

Keyword(s):

Recurrence Relation ◽

Real Line ◽

Summable Function ◽

Type Function ◽

The Real ◽

Definition Of ◽

Derivatives Of

The incomplete gamma type function ?*(?, x_) is defined as locally summable function on the real line for ?>0 by ?*(?,x_) = {?x0 |u|?-1 e-u du, x?0; 0, x > 0 = ?-x_0 |u|?-1 e-u du the integral divergining ? ? 0 and by using the recurrence relation ?*(? + 1,x_) = -??*(?,x_) - x?_ e-x the definition of ?*(?, x_) can be extended to the negative non-integer values of ?. Recently the authors [8] defined ?*(-m, x_) for m = 0, 1, 2,... . In this paper we define the derivatives of the incomplete gamma type function ?*(?, x_) as a distribution for all ? < 0.

Iterative Computation of Higher Derivatives of Repeated Eigenvalues and the Corresponding Eigenvectors

Linear Operators and Matrices ◽

10.1007/978-3-0348-8181-4_6 ◽

2002 ◽

pp. 43-54 ◽

Cited By ~ 3

Author(s):

Alan L. Andrew ◽

Roger C. E. Tan

Keyword(s):

Iterative Computation ◽

Repeated Eigenvalues ◽

Higher Derivatives ◽

Derivatives Of

An Introduction to Finite Differencing

An Introduction to Global Spectral Modeling ◽

10.1093/oso/9780195094732.003.0004 ◽

1998 ◽

Author(s):

T. N. Krishnamurti ◽

H. S. Bedi ◽

V. M. Hardiker

Keyword(s):

Finite Difference ◽

Finite Differences ◽

Single Point ◽

Finite Differencing ◽

Finite Difference Approximations ◽

Difference Approximations ◽

Student Reading ◽

Higher Derivatives ◽

Derivatives Of

This chapter on finite differencing appears oddly placed in the early part of a text on spectral modeling. Finite differences are still traditionally used for vertical differencing and for time differencing. Therefore, we feel that an introduction to finite-differencing methods is quite useful. Furthermore, the student reading this chapter has the opportunity to compare these methods with the spectral method which will be developed in later chapters. One may use Taylor’s expansion of a given function about a single point to approximate the derivative(s) at that point. Derivatives in the equation involving a function are replaced by finite difference approximations. The values of the function are known at discrete points in both space and time. The resulting equation is then solved algebraically with appropriate restrictions. Suppose u is a function of x possessing derivatives of all orders in the interval (x — n∆x, x + n∆x). Then we can obtain the values of u at points x ± n∆ x, where n is any integer, in terms of the value of the function and its derivatives at point x, that is, u(x) and its higher derivatives.

Symbolic Powers of Regular Primes

Canadian Journal of Mathematics ◽

10.4153/cjm-1981-102-2 ◽

1981 ◽

Vol 33 (6) ◽

pp. 1331-1337 ◽

Cited By ~ 1

Author(s):

Yasunori Ishibashi

Keyword(s):

Prime Ideal ◽

Finite Type ◽

Polynomial Ring ◽

Type A ◽

Symbolic Power ◽

Perfect Field ◽

Symbolic Powers ◽

Higher Derivatives ◽

Differential Filtration ◽

Derivatives Of

In a recent paper [6], P. Seibt has obtained the following result: Let k be a field of characteristic 0, k[T1, … , Tr] the polynomial ring in r indeterminates over k, and let P be a prime ideal of k[T1, … , Tr]. Then a polynomial F belongs to the n-th symbolic power P(n) of P if and only if all higher derivatives of F from the 0-th up to the (n – l)-st order belong to P.In this work we shall naturally generalize this result so as to be valid for primes of the polynomial ring over a perfect field k. Actually, we shall get a generalization as a corollary to a theorem which asserts: For regular primes P in a k-algebra R of finite type, a certain differential filtration of R associated with P coincides with the symbolic power filtration (P(n))n≧0.